Swine vaccination system

ABSTRACT

A system for vaccinating swine according to one embodiment includes a housing having an open first end and an open apposite second end. The housing has a pair of side walls that are angled and non-parallel to one another such that at the second end only a single piglet can exit at one time. The system also includes a vaccination station for individually vaccinating piglets. The vaccination station is located between the pair of side walls in a region thereof that is sized to only permit one piglet to stand between the side walls. The vaccination station includes at least one sensor that detects the presence of the one piglet within the vaccination station and at least one spray nozzle positioned within the vaccination station such that a vaccine dose discharged therefrom is directed upwardly into facial areas of the piglet effectively.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a divisional of U.S. application Ser. No.13/864,130, filed Jul. 22, 2010, which was the National Stage ofInternational Application No. PCT/US09/32363, filed Jan. 29, 2009, whichclaims the benefit of U.S. Provisional Application No. 61/025,202, filedJan. 31, 2008, all of which are expressly incorporated herein byreference in their entirety.

BACKGROUND

Swine, when raised commercially, typically are vaccinated to preventinfectious diseases which otherwise could rapidly propagate to infectall swine housed together. Swine producers should vaccinate their pigsto prevent o decrease economic loss from important infectious diseases.Infectious diseases are caused by microorganisms, such as bacteria orviruses. As is known, vaccines contain “safe” microorganisms which areinjected into a pig to prepare its immune system to resist diseases.Swine should be vaccinated for a disease before they will encounter themicroorganisms causing it.

Leptospirosis (lepto) is a disease which can cause abortion. Sows andgilts should be vaccinated against Leptospirosis bacteria beforebreeding. Many lepto vaccines call for gilts to be vaccinated twicebefore breeding, while sows should receive a single booster vaccinationat every weaning.

For sonic piglet diseases, such as scours caused by E. coli bacteria,often the best strategy is to vaccinate the sow before farrowing. Thevaccination increases the concentration of antibodies in the sowscolostrums, or first milk produced after farrowing. These antibodies areabsorbed into the piglets' bodies, providing temporary protection untiltheir immune systems are able to provide their own.

Swine are routinely vaccinated for: (1) Atrophic rhinitis (Pasteurellamultocida type A and toxigenic type D and Bordetellabronchiseptica)—infection with these organisms can cause deviation ofthe snout and increases respiratory disease on some farms. Females arevaccinated before farrowing so they will pass on protection to theirpiglets in the colostrums (first milk after farrowing); (2) E.Coli—infection of baby pigs with types of this bacteria from fecalcontamination of the environment can cause severe scours; (3) Erysipelas(Erysipelothrix rhusiopathiae)—infection with this bacterium can spreadthroughout the body of growing pigs. It can cause death or can localizein the joints, causing chronic arthritis or heart infections; and (4)Leptospirosis—infection of susceptible pregnant females with theLeptospira bacterium can result in abortion. There are a number of otherdiseases that can be the subject of a vaccination, e.g., H1N1 influenzavirus is referred to as traditional swine flu and the H3N2 influenza,virus is referred to as new swine flu. Other diseases include PorcineCircovirus (PCV) which can lead to postweaning multisystemic wastingsyndrome (PMWS) which over time results in significant depletion oflymphocytes, the PRRS virus (porcine reproductive and respiratorysyndrome virus), a.k.a. the Mystery Swine Disease Syndrome, which causesabortions, stillbirths, mummies, and weakborn piglets, and Mycoplasmahyopneumoniae which produces a chronic bronchopneumonia. Vaccination ofswine on a commercial scale is typically accomplished by injection whereeach pig is individually injected with vaccine. There are severalinjection types and placements. More specifically, the injection can bea subcutaneous injection where the injection is under the skin (e.g.,loose flaps of skin in the flank and elbow or behind the ears). Theinjection can be an intramuscular injection where the injection is intothe muscle (e.g., spot on the neck just behind and below the ear). Theinjection can be an intraperitoneal injection where the injection is inthe abdominal cavity. The injection can be an intravenous injection inthe vein. The injection can be an intranasal injection in the nasalpassages. In all these vaccination procedures, a needle of appropriatesize is used and the pig is injected is an appropriate place.

While, spray vaccinator systems have been developed for the poultryindustry, these systems are specifically tailored for this industry andare not suitable for use with swine. More specifically, in sprayvaccinator systems, the chicks are sprayed with a solution containingthe desired vaccination. The spray enters the body or each chick throughits mucous membrane, typically at the eyes or nostrils of the chick, andthereby accomplishes the desired vaccination. Additionally, the natureof preening (running their beaks through their feathers or scratchingtheir heads with a toe) allows uptake of vaccine that is deposited overthe feathers of the chick and is considered a part of the vaccinationprocess. This also results in the spray entering the mucous membrane ofthe chick. Examples of poultry vaccination systems are disclosed in Pat.Nos. 4,449,968 and 4,850,997. However, in all these systems, a cabinetor tray or the like is provided for receiving and holding a number ofchicks (e.g., 100 chicks). The spray mechanism typically includes ashower device that is located above the cabinet and sprays the vaccinedownwardly into the open top and onto the chicks. The droplets thus landon the upper body portions of the chicks. While these systems aresuitable for use with a large number of small chicks that can be placedinto the floor of the cabinet, this arrangement is not suitable forswine which has a much larger size and is also more mobile. In addition,unlike chicks, swine do not preen themselves and thus, a more preciseand direct delivery of the vaccination into the mucous membrane isneeded.

There is thus a need for a spray vaccination system that is specificallydesigned for use with swine.

SUMMARY

A system for vaccinating swine according to one embodiment includes ahousing having an open first end and an open opposite second end. Thehousing has a pair of side walls that are angled and nonparallel to oneanother such that at the second end only a single piglet can exit at onetime.

The system also includes a vaccination station for individuallyvaccinating piglets. The vaccination station is located between the pairof side walls in a region thereof that is sized to only permit onepiglet to stand between the side walls. The vaccination station includesat least one sensor that detects the presence of the one piglet withinthe vaccination station and at least one spray nozzle positioned withinthe vaccination station such that a vaccine dose discharged therefrom isdirected upwardly into facial areas of the piglet effectively.

In another embodiment, a system for vaccinating swine includes a housinghaving an open first end that serves as an entrance and an open oppositesecond end that serves as an exit. The housing is defined by a wall thattapers inwardly toward the second end. The housing is angled relative toa ground plane such that the second end is positioned lower than thefirst end to cause the housing to slope downward from the first end tothe second end.

The system also includes a vaccination station for individuallyvaccinating piglets. The vaccination station is located within thehousing between the first and second ends. The vaccination stationincludes at least one sensor that detects the presence of the one pigletwithin the vaccination station and at least one spray nozzle positionedwithin the vaccination station such that a vaccine dose dischargedtherefrom is directed upwardly into facial areas of the pigleteffectively.

As used throughout, the term spray nozzle is used to define either asingle discharge orifice or multiple discharge orifices grouped into onefixture, e.g. a “spout” or a “shower head” type design. Further, thevaccine dose discharged through the spray nozzle can be in liquid,aerosol, or gas form. Furthermore, the spray pattern from the nozzle canvary from a single stream to a pattern of multiple divergent streams toa mist.

BRIEF DESCRIPTION OF THE DRAWING FIGURES

FIG. 1 is a top plan view of a swine spray vaccination system accordingto one embodiment;

FIG. 2 is a side elevation view of the swine spray vaccination system ofFIG. 1;

FIG. 3 is a side elevation view of a swine spray vaccination systemaccording to another embodiment;

FIG. 4 is a side elevation view of a swine spray vaccination systemaccording to yet another embodiment;

FIG. 5 is an end elevation view of the swine spray vaccination system ofFIG. 1;

FIG. 6 is a side elevation, in partial cross-section, of a swine sprayvaccination system according to another embodiment;

FIG. 7 is a side perspective view, in partial cross-section, of a swinespray vaccination system according to another embodiment;

FIG. 8 is a perspective of a swine spray vaccination system according toyet another embodiment; and

FIG. 9 is a top view of a swine spray vaccination system according to afurther embodiment.

DETAILED DESCRIPTION

Referring first to FIGS. 1, 2 and 5 which illustrate a swine sprayvaccination system 100 according to one embodiment. The system 100 caninclude a housing 110 that is formed of a floor 120, a first side wall130 and a second side wall 140. The first and second side walls 130, 140are upstanding walls that are spaced apart from one another. The sidewalls 130, 140 are not parallel to one another but instead are angledwith respect to one another. As shown, the side walls 130, 140 areangled inwardly toward one another such that first ends 132, 142 of theside walls 130, 140 are spaced further apart from second ends 134, 144of the side wails 130, 140. As shown in the top view of FIG. 1, the sidewalls 130, 140 are arranged generally in as “V” shape.

The housing 110 has a first end or an entrance 150 through which anumber of piglets enter the housing between the side walls 130, 140,where the side walls 130, 140 are maximally spaced apart from oneanother. At an opposite end of the housing 110, a second end or exit 160is provided through which each piglet exits the housing 110.

It will be appreciated that the housing 110 can be in the form of a boxor tunnel structure and contains a narrowing chute that directs thepiglets toward the exit 160 so as to allow for the vaccination ofindividual piglets. In particular, a group of piglets are directed intothe entrance 150 of the housing 110 onto the floor 120 between the sidewalls 130, 140. The narrowing chute construction of the housing 110causes as metering effect of the piglets since as the piglets movetoward the exit 160, the tapering of the side walls 130, 140 causes onlya single piglet to advance toward and into a vaccination station orregion 200 where the piglets are vaccinated in an individual manner. Inother words, the width between the walls 130, 140 in a region justbefore the vaccination station 200, within the vaccination station 200,and from the vaccination station 200 to the exit 160 only accommodatesone piglet.

The use of system 100 is ideal during weaning of piglets from sows andprior to placement in finishing areas. The herding of piglets toward thehousing 110 and then into the entrance 150 and alone the floor 120 tothe station 200 and finally the exit 160 allows individual vaccinationof the piglet. The vaccination station 200 is thus located proximate tothe exit 160 but in any event it is located where only a single pigletcan be disposed between the two side walls 130, 140.

The vaccination station 200 includes one or more sensors 300 fordetecting the presence of the piglet in the station 200. The sensor orsensors 300 can be any number of different types of sensors so long asthey are cable of detecting the presence of the piglet in the station200. For example, the sensor 300 can be of the type that detects theweight of the piglet and based on a detected difference in weight in atarget area (sensor location), the sensor 300 sends a signal to a mastercontroller indicating the presence of the piglet. The sensor 300 canalso be of the type that detects movement of the piglet in the targetarea (sensor location) and then sends a signal to the master controller.The control signal is used to time the application of the vaccination tothe piglet in the vaccination station 200.

The sensor 300 can be in the form of an optical sensor which detects thepiglet when the piglet breaks the beam of the optical sensor as thepiglet enters the vaccination station 200.

The vaccination station 200 also includes a means 400 for individuallyapplying the vaccine to the piglet. According to the present invention,the application means 400 is in the form of a device that is capable ofspraying the vaccine so as to administer the vaccine to the piglet. Thespray means 400 is configured and located so that the vaccine is appliedas to fine or course spray, as warranted by the vaccinating agent, whichis delivered to the facial area of the piglet. For example and accordingto one embodiment, the spray means 400 is in the form of at least oneand preferably a plurality of nozzle devices which spray the vaccineonto the piglet.

The spray nozzle 400 is located within housing 110 so as to deliver thevaccination to the facial area of the piglet. Thus, and in completecontrast to a traditional poultry spray system, the spray nozzle 400 ornozzles 400 are located not above the housing 110 but are below thepiglet such that the vaccine is directed upwardly into the face of thepiglet. For example, the vaccinating nozzle 400 can be angled to theethe piglet and is configured to spray in a fan action delivering theentire dose of vaccine in an appropriate diluent. This spray nozzlearrangement is advantageous due to the fact that piglets tend to facedown when standing or moving from one spot to another spot.

The spray nozzle 400 can be located along the floor of the housing 110or it can be located along the bottom sections of one or more of thewalls 130, 140 so long as the nozzle sprays upwardly toward the face ofthe piglet. The spray nozzle 400 can be recessed within a slot orcompartment in the floor 120 and a screen or the like can be providedover the recess to prevent the piglet from stepping on the spray nozzle400.

In one embodiment, the spray nozzle 400 is of a type that has a variablespray feature in that the spray characteristics of the nozzle 400 can bevaried depending upon the particular application. For example, thenozzle 400 includes a nozzle head 410 that can be manipulated rotated)to change the spray characteristics or spray pattern. In one setting,the spray nozzle 400 can be configured to deliver a fine mist; inanother embodiment, it delivers a course mist; in another embodiment, itdelivers a pulsed spray, etc.

In another embodiment, the spray nozzle 400 is of a movable type in thatonce activated, the spray nozzle 400 can rotate or pivot so as todeliver the vaccine over a target area as opposed to spraying a straightstream. The range of movement of the nozzle 400 is designed so as tospray toward and into the face of the piglet before the piglet exits thehousing 110.

As shown in FIGS. 1 and 2, in the illustrated embodiment, the spraynozzle 400 that is associated with the floor 120 is positioned close tothe exit 160 and beyond the sensor 300 such that the sensor 300 detectsthe piglet first and then as the piglet continues to move toward theexit 160, the piglet walks into the spray that is being discharged fromthe nozzle 400, thereby being exposed to the dose of vaccination.

In yet another embodiment, shown in FIGS. 3 and 4, in addition to thevaccine spray coming from the bottom of the housing 110 (the floor), thevaccine can also be sprayed from sides aimed at the nose, eyes and mouthto immunize both the conjunctive associated lymphoid system (CALT) andthe gut associated lymphoid system (GALT). The spray nozzles 400 areassociated with one or more of the side walls 130, 140. In particular,the spray nozzles 400 are positioned along the side walls 130, 140 so asto direct the vaccine upwardly toward the facial area of the piglet.

FIG. 3 shows a plurality of spray nozzles 400 oriented vertically alongone or both of the side walls 130, 140. Each of the spray nozzles 400communicate with a controller and are fluidly connected to a source ofvaccine such that the controller can instruct one or more of the nozzles400 to be actuated to discharge the vaccine dose. Thus, when largeranimals are being sprayed, the controller will select one or more spraynozzles 400 that are at an elevated height and conversely, when smalleranimals are being sprayed, the controller can instruct one or more lowerspray nozzles 400 to be actuated. The actuation of the spray nozzles 400can be triggered based on input from the sensor 300. A plurality ofoptical beams disposed at varying heights can be triggered to determinethe height of each piglet. Based on the height determined by the sensor300, the particular spray nozzles 400 can be triggered for an optimaldischarge pattern into the piglet's facial area. Further, a similardetermination can be made using at weight sensor and a relationshipbetween the mass of the piglet and height.

Each nozzle 400 is fluidly connected to the source using conventionalmeans, such as a conduit, and each of the conduits from the nozzles 400can be fluidly connected to a main line that leads to the source.

In yet another embodiment shown in FIG. 4, the spray nozzles 400 thatare associated with at least the side walls 130, 140 are adjustable innature to permit the spray nozzles to be positioned at a desireddistance from the floor 120. For example, the spray nozzles 400 can bepart of a track system in which the spray nozzle 400 is securely heldwithin a vertical track member 401. Any number of different mechanisms,including clamps, etc., can be used to hold the spray nozzle 400 withinthe track at a predetermined location thereof and thus, at apredetermined distance from the floor 120.

The spray nozzles 400 can be automatically or manually adjusted. Forexample, the spray nozzles 400 can be part of a motorized assembly inwhich the location of the spray nozzles 400 can be changed byinstructing a motor to drive the nozzles 400 along a vertical track 401to a desired height. For example, when larger piglets are herded anddirected into the housing 110, the nozzles 400 are moved to a higherheight so that the vaccination spray therefrom is directed at the facialarea of the piglet. In both the manual and automatic arrangements, thenozzle 400 travels along the track 401 (vertical track) to permit thenozzle 400 to be positioned at a select distance (height) from the floor120 of the housing 110. The automated adjustment can also be madesimilar to the above embodiment using input from the sensor 300 todetermine the height of the piglet.

It will be appreciated that even when nozzles 400 are included on theside walls 130, 140, the nozzles 400 are still oriented relative to thefacial area of the piglet such that the vaccine is sprayed upwardly intothe facial area of the piglet regardless of the size of the piglet.

Accordingly, in contrast to traditional spray mechanisms designed forchicks, the spray component (nozzles 400) of the system 100 works fromthe base up rather than the top down as for the chicks. Additionally,the time of vaccination is different for chicks who are normallyvaccinated soon after hatch and in the present system 100, the pigletsare vaccinated at the time of weaning. This time is also an opportunetime for the vaccination as maternal antibodies are waning at 15-18 daysof age when the vaccination is completed.

The timing of the spray vaccination is such that once the sensor 300 istriggered upon detection of a piglet in the vaccination station 200, thevaccine is immediately applied via a spray and the nozzles 400 arepositioned so that even if the piglet continues to move toward the exit160, there is sufficient time for the entire vaccine dose to be appliedto the facial area of the piglet.

After receiving the vaccine dose, the piglet continues toward and exitsthe system 100 through the exit 160. At which time, another pigletenters the vaccination station 200 where it is sprayed with vaccine asdescribed above.

Now turning to FIG. 6 in which another vaccination system 500 accordingto another embodiment is illustrated. The system 500 is similar to thesystem 100 and includes a number of elements common in the system 100;however, the system 500 is configured to include a means 600 fortransporting the piglet into and/or through the system 500. The means600 is an automated means that is constructed to move the piglet fromone location to another location and in particular, from a locationoutside of the housing 110 to the vaccination station 200 and then to alocation outside of the housing 110 post vaccination.

In one embodiment, the means 600 is in the form of a conveyor, such asan endless loop conveyor, that is arranged to run at least partiallyalong the floor 120 of the housing 110. This arrangement permits thepiglets to be individually fed and loaded on the conveyor 600 and thendelivered to the vaccination station 200 where they are individuallyvaccinated.

In addition, the means 600 (conveyor) includes as device or mechanism610 for grasping or holding the piglet as it is moved along toward andinto the vaccination station 200. The device 610 can be in the form of apost or clamp device that grasps and holds the piglet. The device 610thus serves to restrain and limit the movement of the piglet as themeans 600 transports the piglet from one location to the other location.Once the piglet is vaccinated, the device 610 is either manually orautomatically disengaged to release the piglet. In any event, the pigletis released from the device 610 and is free to be moved to anotherlocation post vaccination.

The system 500 can also include a receptacle 650 that that receives thepiglets post vaccination. In the illustrated embodiment, the receptacle650 is in the form of a crate or the like. In this embodiment, theconveyor 600 is configured so that the piglets are directed into thereceptacle 650 after each piglet has been individually vaccinated.

In embodiment of FIG. 6, the main spray nozzle 400 can be stillassociated with the floor 120 in that it the conveyor 600 does not haveto occupy the complete width of the floor 120 but can be a sectionthereof. Thus, the spray nozzle 400 can be formed to one side of theconveyor 600 but is still configured so that is sprays upwardly so as todeliver the vaccine dose to the facial area of the piglet.Alternatively, as shown, the floor 120 can be located adjacent one endof the conveyor 600 such that the piglets are delivered to the floor 120or over the floor 120 to be placed into position where they arevaccinated.

In traditional handling arrangements, piglets are handled by personneland moved to a receptacle, like crate 650, as the personnel wean themfrom the sow. The practice is to hold the piglets by their hind legs andthen drop the piglets into the receptacle 650 that is then used to movethem to a grow out area. In the embodiment illustrated in FIG. 7, avaccination system 700 is provided that is designed for use withreceptacle 650. The vaccination system 700 is configured in the form ofa chute 710 that includes a first end or entrance 712 and an oppositesecond end or exit 714 that is positioned proximate the receptacle 650such that when the piglet exits the chute 710, it is delivered into thereceptacle 650. For example, the exit 714 can be operably attached tothe receptacle 650 to permit the piglet to be delivered into thereceptacle 650.

The chute 710 is constructed similar to the housing 110 of FIG. 1 inthat it includes one or more sensors 300 and one or more spray nozzles400 for delivering a vaccine dose to the facial area of the piglet as ittravels within the chute 710. For example, the chute 710 hasincorporated therein one or more sensors 300 to detect the presence ofthe piglet at a target area. Since the chute 710 is inclined at an anglethat causes the inserted piglet to slide down the chute 710 toward theexit 714, the sensor 300 is located and is configured to detect thepiglet as it slides within the chute 710. In one embodiment, the sensor300 is in the form of an optical sensor and it detects the piglet assoon as the piglet breaks the beam emitted by the optical sensor 300. Aswith the other system, the triggering of the sensor 300 causes a controlsignal to be sent to the master controller which then communicates withand instructs the spray nozzle 400 to administer the vaccine dose.

Accordingly, downstream of the sensor 300 one or more spray nozzles 400are provided inside the chute 710. As with all other embodiments, thespray nozzles 400 are positioned so as to spray the vaccine dose in anupwardly manner so that the vaccine dose is delivered to the facial areaof the piglet. Since the chute 710 can be a cylindrical tube structure,at least one spray nozzle 400 is disposed along the floor or bottom ofthe chute 710 to ensure that the vaccine dose is administered to thefacial area (snout) of the piglet. The spray nozzle(s) 400 can thus belocated close to the exit 714 of the chute 710 or they can be locatedcloser to the middle or the chute 710. While the chute 710 preferablyincludes one spray nozzle 400 along the floor of the chute 710, it alsocan include one or more nozzles 400 that are located at higher(elevated) positions relative to the nozzle 400 that is formed along thefloor of the chute 710.

As with the other embodiments, the sensor 300 is not limited to being amotion (optical) sensor but it can be other sensors including as mass(weight) sensor.

The exit 714 of the chute 710 can be positioned so that receptacle 650can move thereunder. Thus, once one receptacle 650 is filled, it can bemoved and another can be delivered underneath the chute 710 withoutmoving the chute 710.

In yet another embodiment shown in FIG. 8, a spray vaccination system800 is illustrated and includes a spray applicator 810 in the form of acone that has at least one open end 812 that represents the greatestdiameter of the cone. The end 812 has a diameter that is great enough topermit at least the facial area (snout) of the piglet to be receivedtherein. At an opposite end 814, the cone includes at least one spraynozzle (not shown) that is oriented to spray the vaccine dose toward thefacial area of the piglet. As the piglets are moved, each piglet is heldby its hind legs and is “dunked” into the cone 810 and the detection orpresence of the snout activates the spray nozzle. The piglet can thus begrasped by its hind legs using an automated mechanism or the piglet canbe held by its hind legs by a person who then maneuvers the upside downpiglet to the spray vaccination system 800. Preferably, the piglet'shead/snout fits tightly and neatly in the cone, thereby trapping thesnout in the cone and preventing movement and allowing an accurate“take” of the vaccine.

The spray nozzle can be triggered to operate using any number ofdifferent techniques, including both manual and automated techniques.For example, when a manual technique is used, a lever, switch, button,etc., 820 is used to actuate the spray nozzle once the facial area ofthe piglet is in the proper position within the cone. In FIG. 8, themechanism 820 is a foot activated actuator (e.g., foot pedal),whereupon, when the operator steps thereon, the spray mechanism isactuated for a prescribed period of time to discharge a dose ofvaccination.

Alternatively, the spray nozzle is automatically actuated once thefacial area of the piglet is detected. For example, one or more sensors(not shown) 819 can be employed with the cone and are configured todetect the facial area (snout) of the piglet (e.g., the snout of thepiglet can break as beam that is part of an optical sensor). In anotherembodiment, the sensor is a touch activated sensor, whereby contact ofthe snout to the sensor sends a control signal to the master controllerto cause a spray of the vaccine (the vaccine dose) to be generated anddelivered to the facial area of the piglet. In all embodiments, theamount and time period that the spray is discharged can be controlledusing any number of different techniques. For example, the spray nozzlecan be deactivated as soon as the sensor no longer detects the pigletwithin the cone (e.g., when the beam of the optical sensor is restored).Alternatively, the spray nozzle is simply activated for a given amountof time that results in the desired quantity of vaccine being dischargedfrom the spray nozzle. It will be understood that the spray volume canbe adjusted to deliver the appropriate dose and droplet size of thevaccine can be adjusted for the best “lake” of the vaccine.

When automated, a number of piglets are successively “dunked” in thespray applicator 810.

In the illustrated embodiment, the spray nozzle includes a source 401 ofvaccination and in particular, the source 401 can be in the form of acontainer or bottle that stores the vaccination. The source 401 isconnected to the other operative components of the spray nozzle andtherefore, once activated, the vaccination is withdrawn from the source401 as by using a pump or the like and then discharged through the spraynozzle into the conically-shaped body 810. In order to permit “dunking”of the piglet, the cone shaped spray nozzle is vertically oriented withits opening facing upward. This allows the piglet to be easily held andinserted snout first into the spray nozzle.

The mechanism 800 can include other operative parts, including pressureregulators and indicators to show the level of the fluid in the sourcecontainer 401, as well as whether the fluid in source container 40 isempty.

In a further embodiment, FIG. 9 illustrates system 900 utilizing, adivided housing 910 that subdivides into smaller housings 912, 914, 916,918. The housing 910 further has a floor 920 and first and second sidewalls 930, 940 disposed perpendicular to the floor 920. Intermediatewalls 932, 934, 936 are disposed within the housing between the firstand second side walls 930, 940 and can be equally spaced apart. Theintermediate walls 932, 934, 936 can form each of the smaller housings912, 914, 916, 918 which are sized to accept one piglet. In theillustrated embodiment, first and second side walls 930, 940 and theintermediate walls 932, 934, 936 are disposed parallel to each other, inchute fashion. However, all or some of the walls 930, 932, 934, 936, 940can be non-parallel to each other to form “V” shapes for the housing 110or smaller housings 912, 914, 916, 918.

In operation, a number of piglets enter the housing via an entrance 950located on one end of the housing. As the piglets move through thehousing 110 they encounter the intermediate walls 932, 934, 936, whichlead to sub-entrances 952, 954, 956, 958 dividing individual pigletsinto each of the smaller housings 912, 914, 916, 918. As the pigletenters the smaller housings 912, 914, 916, 918 it triggers sensor 300which in turn activates spray nozzle 400 to discharge in the facial areaof each piglet. In a particular embodiment, each spray nozzle 400 a, 400b, 400 c, 400 d is disposed at or near the exit of the housing 960 whichis divided in sub-exits 962, 964, 966, 968 for each of the smallerhousings 912, 914, 916, 918. Further, each spray nozzle can becontrolled by an individual sensor 300 a, 300 b, 300 e, 300 d or can begenerally trigged by sensor 300 as piglets move through thesub-entrances 952, 954, 956, 958. As noted above, spray nozzles 400 canbe fixed, or movable, but positioned to discharge generally upwards andinto the facial area of the piglet.

The age of the swine will depend upon which vaccination is beingapplied. For example, the swine can have an age of 15 to 18 days whichis a suitable age for applying a number of different vaccinations.Vaccinations that can be delivered by the above can include, but are notlimited, to vaccinations for Atrophic rhinitis (Pasterurella multocidatype A and toxigenic type D, Bordella bronchiseptica, E. Coli,Erysipelas (Erysipelothrix rhusiopathiae), Leptospirosis, Traditionaland New Swine Flues, the Porcine Circovirus (PCV), the PRRS virus, andMycoplasma hyopneumoniae.

The present invention is not to be limited in scope by the specificembodiments described herein. Indeed, various modifications of theinvention in addition to those described herein will become apparent tothose skilled in the in from the foregoing description and accompanyingfigures. Such modifications are intended to fall within the scope of theappended claims. Doubtless numerous other embodiments can be conceivedthat would not depart from the teaching of the present invention whosescope is defined by the following claims.

That which is claimed:
 1. A system for vaccinating swine comprising: ahousing having an open first end that serves as an entrance and anopposite second end, the housing being defined by a wall that tapersinwardly toward the second end, the housing being angled relative to aground plane such that the second end is positioned lower than the firstend to cause the housing to slope downward from the first end to thesecond end; and a vaccination station for individually vaccinatingpiglets, the vaccination station being located within the housingbetween the first and second ends, the vaccination station including atleast one sensor that detects the presence of the one piglet within thevaccination station and at least one spray nozzle positioned within thevaccination station such that a vaccine dose discharged therefrom isdirected upwardly into facial areas of the piglet effectively.
 2. Thesystem of claim 1, wherein the housing has a frustoconical shape.
 3. Thesystem of claim 1, wherein the second end is open and serves as an exit.4. The system of claim 3, wherein one spray nozzle is disposed at ornear a bottom surface of the housing on which the piglet slides towardthe second end and one or more other spray nozzles are provided andelevated relative to nozzle proximate the bottom surface and oriented tospray the vaccine dose into the eyes and nose of the piglet.
 5. Thesystem of claim 4, wherein the elevated spray nozzle is verticallyadjustable within a track to permit a height of the other spray nozzlerelative to the bottom surface to be adjusted.
 6. The system of claim 5,wherein the spray nozzle is part of an automated system and is drivenwithin the track to a desired height by action of a controller.
 7. thesystem of claim 1, wherein the spray nozzle includes a movable head thatsprays the vaccine dose in a fan action.
 8. The system of claim 1,wherein the at least one sensor comprises a motion sensor.
 9. The systemof claim 1, wherein the at least one sensor is a mass sensor thatdetects the weight of the piglet in the vaccination station.
 10. Thesystem of claim 1, wherein the spray nozzle is oriented at an angle of45 degrees relative to the bottom surface of the housing resulting in atleast sonic of the vaccine dose being discharged at an angle of 45degrees relative to the bottom surface.